Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
Case 145
-1- 2087310
OPERATOR FOR AN AWNING TYPE WINDOW
BACKGROUND OF T~IE INVENTION
Technical Field
The present invention is directed toward a window operator, and more
5 particularly toward an opel~tor for opening and closing an awning type window.
Ba-~k~round Art
Manually operable window Op~ldtOI~ for casement and awning type
windows are well known in the art.
In casement type windows, a window and sash are mounted for pivot-
10 ing about one of the vertical sides, and the operator connects to an adjacent side forpivoting the sash for opening and closing. A variety of operators usable with case-
ment type windows are shown, for example, in commonly owned Van Nompenburg
et al. Patent No. 4,241,541, P~L~l~on et al. Patent No. 4,253,276, Erdman et al.U.S. Patent No. 4,266,371, Nelson U.S. Patent NoO 4,305,228, Allen U.S. Patent
No. 4,823,508, Tucker U.S. Patent No. 4,840,075, and Nolte et al. U.S. Patent
Nos. 4,843,703 and 4,845,830.
With awning type windows, the window and sash are mounted for piv-
oting about one of the horizontal sides (generally the top side), and the opelator
connects to the opposite side to control opening and closing of the sash. An operator
20 usable with awning type windows is shown, for example, in my commonly owned
U.S. Patent No. 4,617,7580
Naturally, operators for the different types of windows have some
common features. For example, with either type window, it is typical for the opera-
tor to have a mounting base which rotatably mounts a gear and pull arm The gear
25 meshes with a worm gear on a worm shaft having a handle affixed thereto and a pull
Case 145
-2- ~ ~3 8 ~ 3 ~ ~
arrn is operatively connected to a window whereby rotation of the worm shaft results
in rotation of the gear and the pull arm for window movement.
Nevertheless, it is well understood by those having skill in the art that
operators for awning type windows not only operate differently than operators for
5 casement type windows (due to the different movement of the sash relative to the
operator base), but they encounter and must be able to withstand distinctly different
forces and stresses during operation. For example, motion of the bottom portion of
the pivoting sash of an awning type window is both out and up relative to the frame;
there is no lateral (sideways) motion. Accordingly, it is desirable to minimi7e any
10 lateral forces introduced to the sash by the operator, since such forces are counter-
productive, can Imnecess~rily stress and therefore damage the hinges at the top of the
sash, can cause the sash to not provide a proper weather seal, and can even prevent
the operator from properly working.
Of course, it is also more generally desirable for any such operator to
15 be easily and inexpensively manufactured and in~t~ It is still further desirable
for such O~l~tOl~ to provide reliable and smooth operation over the long life ofwhatever awning type window structure it controls for opening and closing.
SUIUMARY OF T~iE INVENTION
In one aspect of the present invention, an operator is provided for an
20 awning type window having a sash pivotable about its top side relative to a window
frame, with the opelator controlling opening and closing movement of the sash
relative to the frame. The operator includes a drive gear secured to a base on the
frame, a sun gear pivotable about an axis on the base and drivably eng~ging the drive
gear, a primary arm with a planetary gear fixed thereon and drivably en~ging the25 sun gear, a secondary arm pivotally mounted about a second axis on the base, and a
drive linkage pivotally interconne~ted between the primary arm and the secondaryarm. The primary and secondary arms are connectable to the sash bottom side to
Case 145
~3~ '~8~;3~
control movement of the bottom side toward and away from the frame in response to
rotation of the drive gear.
In another aspect of the present invention, the arm and sash connection
includes a bracket fixed to the sash side opposite the one sash side, a first connecting
5 arm pivotally connected at one end to the primary arm and at the other end to the
bracket, and a second connecting arm pivotally connected at one end to the secondary
arm and at the other end to the bracket. The primary, se~ond~ry, and connecting
arms cooperate to move the sash bottom side toward and away from the frame for
opening and closing of the sash.
In still another aspect of the present invention, the base includes a
fixed primary arm stop which engages the primary arm to prevent lateral shifting of
the sash when closing the sash against the frame.
In yet another aspect of the present invention, the base inch~des a fixed
secondary arm stop which engages the secondary arm to prevent lateral shifting of
15 the sash during initial opening of the sash from a position closed against the frame.
It is an object of the present invention to provide an awning type
window operator which may be easily and inexpensively manufactured as well as
easily and inexpensively installed.
It is another object of the present invention to provide an awning type
20 window operator which provides reliable and smooth operation, without binding and
without d~m~ging the sash hinge, over the long life of the window structure which
it controls.
It is still another object of the present invention to provide an awning
type window operator which ensures that the sash will be properly sealed against the
25 frame.
Case 145
--4--
~731~
BRIEF DESCRIPIION OF T~E DRAWINGS
Fig. 1 is a broken partial view of a closed awning type window includ-
ing the novel operator of the present invention;
Fig. 2 is a view similar to Fig. 1, but showing the window in an
interme~i~te open position;
Fig. 3 is a view similar to Fig. 2, but showing the window in its fully
open position;
Fig. 4 is a broken partial view taken along line 4 of Fig. 2;
Fig. 5 is a perspective view a portion of the operator of the present
invention;
Fig. 6 is a cross-sectional view taken along line 6-6 of Fig. 3;
Fig. 7 is a broken partial view of a closed awning type window having
an ~ltPrn~tive hook member; and
Fig. 8 is a broken partial view of a closed awning type window having
a rib on the operator base.
DESCRIPIION OF T~IE PREFERRED EMBODIMENT
Figs. 1-4 show the window operator 10 of the present invention in
various configurations moving an awning type window from a window sash closed
to a window sash fully open position. (Note that, for purposes of illustration, Figs.
1-4 show the operator 10 as inst~llP~ but with the working components visible, i.e.,
without the protective and decorative o~ldtor cover and frame trim which are
typically used in such in~t~ tions.)
Specifically, the operator 10 includes a base 12 suitably secured to the
window frame 14. A handle 16 is pivotally mounted to the base 12 to allow manualrotation of a worm 18 (see Fig. 5) to control the op~lor 10 as is hereafter de-
scribed.
Case 145
~873~3
A primary or sun gear 20 is pivotally secured to the base 12 for
rotation about an axis defined by a suitable pin such as a rivet 22 (see Fig. 6). As
shown in Fig. 6, a bushing 24 and washer 26 may be advantageously used to help to
ensure reliable, wobble-free rotation of the primary gear 20.
A primary arm 28 is pivotally secured to the base 12 about the same
axis as the primary gear 20, and is pivotally connected to a secondary or planetary
gear 30 which drivably engages the primary gear 20.
The base 12 includes a fixed primary stop 34 which engages the pri-
mary arm base portion 36 during closing of the sash 38 (see Fig. 1) as is described
in greater detail hereafter.
A secondary arm 40 is pivotally secured to the base 12 for rotation
about an axis defined by a suitable pin such as a second rivet 22'.
A fixed secondary stop 42 engages a notch 44 on secondary arm 40
during initial opening of the sash 38 (see Fig. l) as is described in greater detail
hereafter.
A linkage 45 pivotally interconnects the primary arm 28 and the
secondary arm 40. More particularly, the linkage 45 has a drive link 46 rotatably
coupled to a follow link 47 with a pivot pin 48. One end of the drive link 46 and the
secondary gear 30 are mounted about a suitable pin or rivet 49, and one end of the
follow link 47 and the secondary arm 40 are mounted about a suitable pin or rivet
51.
A suitable bracket structure connects the operator 10 to the window
sash 38. Specifically, this structure includes a hook member 60 suitably fLxed to the
sash 38 and an eye member 62 having openings 64 receiving hooks 66 of the hook
member 60 (see Figs. 1-3). Such connections are generally known in the art for
awning type window operators, and commonly include a suitable locking member
(not shown) to allow the hook member 60 and eye member 62 to be connected and
Case 145
-6--
3 1 ~
disconnected when desired for easy in~t~ tion, maintenance, window washing,
and/or egress through the window.
A first connecting arrn 70 is pivotally secured on one end to the
primary arm 28 and on the other end to the eye member 62. A second connecting
S arm 76 is pivotally secured on one end to the secondary arm 40 and on the other end
to the eye member 62.
In order to accommodate the non-linear motion of the sash 38 relative
to the operator base 12 (as a result of the pivotal motion of the sash 38 relative to the
frame 14), the pivotally connect~d ends of the primary arrn 28 and the first connect-
ing arm 70, and the secondary arm 40 and the second connecting arm 76, are dis-
posed at angles relative to their longit~lrlin~l direction as illustrated in Fig. 4 with the
angle of the secondary arm 40 design~t~ "a'. This configuration allows the con-
nected arms 28, 70, and 40, 76 to be disposed generally parallel to each other when
the window sash 38 is closed (with e-~Pnt;~lly no vertical offset up from the frame
14) while also accommodating the increasing amounts of upward movement of the
sash 38 as it is opened.
Operation of the above described O~ dtor 10 is as follows.
As best illustrated in Figs. 1-4, when the window sash 38 is closed
against the frame 14, a person may turn the handle 16 which in turn pivots the worm
180 Pivoting of the worm 18 in turn applies a force (through the driving engagement
of the primary and secondary gears 20, 30) which tends to move both the primary
arm 24, the drive linkage 45, and the secondary arm 40 in a direction to open the
sash 38.
However, because of the sun-planet relationship of the primary and
secondary gears 20, 30, the force applied to the eye member 62 by the primary arm
28 and first conn~cting arm 70 can be twice as much as the force applied by the
secondary arm 40 and the second connecting arm 76. Such a force differential
(resulting in an undesirable net lateral force colll~nent being applied to the sash 38)
Case 145
~7~ ~O~r'31a
is during most operation small enough so as to not damage the hinges used in today's
awning type windows. However, this force differential is much greater when the
window sash 38 is first opened due to the high force required to break the sash 38
free of the weatherstrip mounted to the frame 14 of virtually all windows today.S Specifically, during initial opening it is common for the relatively high
forces generated by the opel~tor 10 to cause a small amount of lateral movement of
the sash 38 until the seal with the weatherstrip is broken. Due to the configuration
of the operator 10, that lateral motion could be great enough to result in the connect-
ed ends of the primary arm 28 and the first connecting arm 70 touching the sash 38.
If that were to occur, the first connecting arm 70 would e-c~P-n~i~lly pass beyond its
connection to the eye member 62, with the result then being that the forces of the
primary and first connecting arms 28, 70 tend to close the sash 38 rather than open
it. Therefore, rather than opening the sash 38 when desired, the operator 10 would
lock up and, if forced by the person trying to open the sash 38, could result indamage to the operator, sash, and/or sash hinge.
The secondary arm stop 42 prevents the above undesirable operation,
however, since it ensures that the secondary arm 40 does not rotate beyond a pre-
ferred configuration. Since lateral movement of the sash 38 is avoided (because the
secondary stop 42 is located so as to engage the notch 44 on the secondary arm 40
in the closed position that results in no lateral shift), the first connecting arm 76 is
prevented from passing beyond its connection to the eye member 62 even during ini-
tial opening when the sash 38 is freed from the weatherstrip. Consequently, the
operator 10 will never lock up
Continued turning of the handle 16 after breaking the seal will contin-
ue to extend the arms 28, 40, 70, 76 to open the sash 38 to the fully open position
(see Fig. 3) or to any desired partially open position (only one of which is shown in
Fig. 2).
Case 145
2 ~ ~ r 3 1 ~
For closing the sash 38, the handle 16 is turned in the opposite direc-
tion to cause the primary gear 20 to be pivoted counterclockwise and thereby pivot
the primary arm 28, the drive linkage 45, and the secondary arm 40 (and therefore
the sash 38) back toward the frame 14.
S When the sash 38 is nearly fully closed, a greater force is again
desirable in order to pull the sash 38 into a tight seal against the weatherstrip.
However, this greater force can again result in a differential lateral force such as
previously described which could laterally shift the sash 38 slightly. Such lateral
shifting, if allowed, could result in the sash 38 being mispositioned relative to the
frame 14 so that the weatherstrip may seal tightly on one side of the sash 38 and not
at all on the other. This is obviously an undesirable situation.
The primary stop 34 prevents the above undesirable operation, howev-
er. Specifically, while the configuration of the operator 10 is such that a greater
force is naturally applied to the primary arm 28 than the secondary arm 40, the
lS primary stop 34 is located so as to engage the primary arm base member 36 in the
closed position that results in no lateral shift. Continued turning of the handle 16
therefore cannot cause any undesirable lateral shift of the sash 38 but instead increas-
es the force to the sash 38 through the secondary and second connecting arms 40, 76
to thereby ensure that the sash 38 is pro~lly sealed against the weatherstrip.
During closing, it is also desirable that a m~im~lm closing force be
applied during the last stages of closing as such forces will act to provide a tight seal
against the weather sealing typically provided around such window frames. In order
to accomplish this, it is prefelled that the drive link 46 and follow link 47 be so
sized and configured that at the last stage of closing they approach a toggle position
(with the pivot pin 48 between them approal~hine a line between the pivot pins 49, 51
at their opposite ends). With such a configuration, the axial force applied on the
follow link 47 (which force applies the turning torque to the secondary arm 40) is
Case 145
-9- ~73~l~
maximized (theoretically appro~ching infinity at the toggle position) to therebymaximize the closing force as mentioned.
It is also desirable to provide an additional force during initial opening
of the window in order to break the window free from the seal along the weather
5 strip typically provided with windows. The above described configuration provides
such operation, as the follow link 47 will pull on the secondary arm 40 with maxi-
mum force relative to the torque applied on the operator handle 16 based on the
"near toggle" position of the drive and follow links 46, 47 during initial opening.
Figures 7 - 8 show ~lt~rn~tive structure for preventing lock up of the
10 operator 10 during initial opening when the sash 38 is freed from a weatherstrip.
Referring to Figure 7, an ~lt~. "~ e bracket structure for connecting
the operator 10 to the window sash 38 incl~ldes an Plong~tP~ hook member 160
suitably fL~ed to the sash 38 and an eye member 62 having openings 64 for receiving
hooks (not shown in Figure 7) of the hook member 160. The hook member 160 has
a pair of integral spaced apart tabs or sash stops 162, 164 which project perpendicu-
larly to the sash 38 and contact a co~ onding one of the connecting arms 70, 76,respectively, when the sash 38 is in a closed position. The sash stops 162 and 164
m~int~in a minimum spacing between the sash 38 and the connecting arms 70, 76 toprevent the connecting arms 70, 76 from passing beyond their connections to the eye
member 62, even during initial opening of the sash 38. Consequently, lock up of the
opel~or 10 is prevented.
Figure 8 shows a rib 80 suitably fixed to the operator base 12, as by
staking. The rib 80 is located so as to engage the base portion 82 of a secondary
arm 40' in the closed position of the operator 10 that results in no lateral shift of the
sash 38. The rib 80 therefore prevents lock up of the o~l~or 10 when the sash 38initially is opened in a manner similar to the secondary arm stop 42 discussed above
with respect to Figs. 1 - 4.
Case 145
-lo- 2~31~
Still further, it should be understood that the operator of the present
invention could be attached to the window sash in a manner different than that
shown. Specifically, for example, the connecting arms 70, 76 could in some applica-
tions be omitted with the primary and secondary arms instead connected to a guide
bar structure in a manner similar to that shown in Vetter U.S. Patent No. 4,617,758,
the complete disclosure of which is hereby inco,~ld~ed by reference.
As will be understood by those who have gained an underst~n-1ing of
the present invention through the disclosure herein, the above described operator 10
will provide reliable and smooth operation, without binding and without cl~m~ging
the sash hinge, over the long life of the window structure which it controls. Further,
this operator 10 will ensure that the sash 38 will provide the desired seal against
weather when closed. Still further, this operator 10 is simple and therefore may be
easily and inexpensively manufactured as well as easily and inexpensively installed
and m~int~inP~.
Still other aspects, objects, and advantages of the present invention can
be obtained from a study of the specific~tinn, the drawings, and the appended claims.
